NL8501451A - SMOOTH SEALING MEMBRANE, IN PARTICULAR FOR ROOFS, FORMED OF A THERMOPLASTIC MATERIAL REINFORCED BY A GRILL OF SYNTHETIC FIBERS AND BY A GRILL OF FIBERGLASS. - Google Patents

Description

r * VO 7191

Flexible sealing membrane, especially for roofs, formed from a thermoplastic material reinforced by a grid of synthetic fibers and a grid of glass fibers.

The present invention relates to a flexible sealing membrane which is particularly suitable for covering and rendering flat roofs impermeable.

The Netherlands patent application 66.10796 and the German patent application 31 50 021 are already known sealing membranes, which are manufactured on the basis of a thermoplastic material such as a chlorinated polyolefin or a terpolymer based on ethylene, propylene and diene. Such membranes are generally reinforced by one or more reinforcing materials such as grids or non-woven or glass fiber coverings or from natural or synthetic fibers incorporated in the bulk of the membranes.

However, it has been found that when such membranes are reinforced with a material based on synthetic or natural fibers, products are obtained which exhibit satisfactory tensile properties under tension but whose shrinkage and dimensional stability are insufficient to be applicable in all designs of allow flat roofs, especially those with free or so-called independent placement.

If, on the other hand, such membranes are reinforced with a glass fiber-based material, products are obtained whose shrinkage and dimensional stability are improved, but whose tensile properties leave much to be desired.

To date, it has not been possible to provide sealing membranes that have an ideal combination of properties, making them particularly suitable for a very wide range of roofing and waterproofing applications.

A sealing membrane has now been found which combines a combination of properties, making it suitable for all modes of application in the above application.

The present invention therefore relates to a flexible sealing membrane, in particular for roofs, comprising a thermoplastic material and a reinforcing system, which incorporates a synthetic fiber grid and a glass fiber grid in the c; i -2- comprises thermoplastic material, the reinforcement grids being chosen such that when the membrane is subjected to a progressively increasing tensile force, the stress exerted at the time of the glass fiber grating breaking is at most equal to 90% of the tensile resistance of the synthetic fiber grid. It has surprisingly been found that the sealing membrane obtained in accordance with the invention not only exhibits shrinkage, dimensional stability and stress tensile properties which are very satisfactory, but also has a combination of mechanical properties such as resistance to bending fatigue and to cracking, etc., which are remarkable and particularly suitable for use of the membrane for covering and waterproofing roofs, regardless of the method of installation.

In one embodiment, the synthetic fiber grid used to reinforce the membrane is generally selected in such a way that it has a tensile resistance of between 30 and 250 daN / 5 cm and according to a preferred embodiment between 50 and 180 daN / 5 cm in each direction, and the glass fiber grid is selected to have a tensile strength generally between 5 and 60 daN / 5 cm and preferably between 20 and 50 daN / 5 cm in each direction wherein the tensile resistance is measured at 20 ° C and with a tensile speed of 10 cm / min. It has actually been found that under these conditions membranes are obtained which have a combination of ideal properties.

Generally, a synthetic grid is used to produce the membrane according to the invention. 2 fibers weighing between 20 and 300 g / m and a glass fiber grid 2 fibers weighing between 10 and 200 g / m. Preferably a grid of synthetic fibers with a weight between 50 and 200 2 2 30 g / m and a grid of glass fibers with a weight between 20 and 150 g / m is chosen.

Generally, a synthetic fiber grid comprising 1 to 5 threads per centimeter in the two directions is used, and a glass fiber grid comprising 1 to 6 threads per centimeter in which the number of threads in each direction may be the same or different.

For the manufacture of the grid from synthetic fibers, use can be made of all known synthetic fibers, in particular 8301451 -3- of fibers based on acrylic resin, based on polyamides or on the basis of polyesters, which latter fibers are preferred. The synthetic fibers can be in the form of monofilaments or of multi-filaments, or also in the form of optionally woven ribbons.

For the manufacture of the grid from glass fibers, use can be made of all known glass fibers and in particular of glass-A, glass-E or also glass-S fibers. The glass fibers can be in the form of mono or multi-filaments.

The thermoplastic material forming the sealing membrane can be any resin commonly used to make sealing membranes. By way of non-limitative examples, mention may be made of the vinyl chloride-based resins, the chlorinated or chlorosulfonated polyolefins and in particular chlorinated or chlorosulfonated polyethylene, the tez polymers or ethylene base, propylene and a diene, the neoprene, the polyisobutenes, the isoprenes, etc., as well as mixtures in all proportions of these resins with one another or with other components such as bitumen, with mixtures of vinyl chloride and chlorinated polyolefin based resins being preferred, and more particularly polyvinyl-based mixtures Chloride and chlorinated polyethylene because of their good flammability property.

The thermoplastic material used to manufacture the sealing membrane may additionally contain conventional additives such as stabilizers, igniters, plasticizers, pigments, dyes, fillers and reinforcement materials, etc.

According to a preferred embodiment, the sealing membrane consists successively of a layer of thermoplastic resin, a grid of glass fibers, a grid of synthetic fibers and a layer of thermoplastic resin, which are joined by hot lamination, for example with the aid of a calender or rubbing device.

According to another possible embodiment, the sealing membrane according to the invention can comprise a single mixed reinforcement grid, which is simultaneously composed of synthetic fibers and glass fibers. In this case, it is, of course, desirable that the tensile resistance imparted to the membrane by the total of the fibers be such as 830 1 45 1 * V% -4 to meet the relationship set forth above. It is also desirable that the glass fibers and the synthetic fibers are uniformly distributed in the reinforcing grid.

The sealing membrane according to the invention generally has a thickness between 0.5 and 3 mm and exhibits an elongation between 12 and 20% and a shrinkage of less than 0 during the breaking of the most resistant element. 3%.

In addition, the sealing membrane of the invention is illustrated in greater detail in the following practical embodiments, in which Examples 1 and 3 are comparative examples not forming part of the invention.

Example 1 (comparison)

Hot lamination produces a membrane consisting of two outer sheets with a thickness of 0.6 mm, realized by 15 calendering starting from a mixture consisting of 75% by weight of chlorinated polyethylene and 25% by weight of polyvinyl chloride, and an inner reinforcement grid of polyester fibers, which comprise 2x2 threads of 1100 decitex each per centimeter and have a tensile strength of 80 daN / 5 cm in the two directions.

The sealing membrane thus produced shows an elongation of 17.6% at the time of breaking of the reinforcement grid. However, it has been found that this membrane additionally has a shrinkage of the order of 0.5% after six hours at 80 ° C and thus the dimensional stability of the membrane is not sufficient to cover the entire range of installation techniques used in roofing, to cover.

Example 2

A sealing membrane is prepared as in Example 1, but the internal reinforced one is, in addition to the polyester fiber grid, a glass fiber grid comprising 30 2x2 threads of 340 decitex each per centimeter and a tensile strength of 18 daN / 5 cm.

A sample of the membrane thus obtained is subjected to a progressively increasing tensile force at 20 ° C and a drawing speed of 10 cm / min. The tensile diagram shows a first peak for a tensile strength of 42 daN / 5 cm, exerted on the membrane as a whole, and corresponding to the breaking of the glass fiber grid, 8501451 m -5- and then a second peak for a tensile force of 80 daN / 5 cm, corresponding to the breaking of the grid from polyester fibers.

Thus, in the membrane of this example, it appears that the stress applied to all of the constituents at the time of the breaking of the glass fiber grid, being 42 daN / 5 cm, is less than 90% of the tensile resistance of the grid. from synthetic fibers (90% of 80 daN / 5 cm).

The membrane of Example 2 exhibits an elongation of 17.8% on breaking the grid from polyester fibers, a shrinkage after six hours at 80 ° C below 0.3%. The membrane therefore shows a combination of properties and in particular a compromise between the elongation at break and the dimensional stability, which are particularly suitable for an application of this membrane for making roofs waterproof and impermeable, regardless of the method of installation.

15 Example 3 (comparison)

The procedure is as in Example 2, except that the glass fiber grating is replaced by a glass fiber grating which also comprises 5x5 centimeters of 340 decitex each per centimeter and has a tensile strength of 44 daN / 5 cm.

A sample of the membrane thus obtained is subjected to an increasing tensile force as in Example 2. It is noted that said tensile diagram shows a first peak for a tensile force of 74 daN / 5 cm applied to the membrane as a whole and corresponding to the breaking of the glass wire mesh, then a second peak for a tensile force of 80 daN / 5 cm, corresponding to the breaking of the polyester fiber mesh.

In the membrane according to example 3, it therefore appears that the stress exerted on the whole of the components at the moment of breaking the glass fiber grid, being 74 daN / 5 cm, is more than 90% of the tensile resistance of the grid from polyester fibers (90% of 80 daN / 5 cm).

The membrane of Example 3 shows a shrinkage of less than 0.2% after six hours at 80 ° C, but its elongation during the breaking of the grid from polyester fibers does not exceed 6.9%.

The membrane therefore exhibits an elongation to break that does not allow for free placement when used in roof impermeability.

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Claims (9)

1. Flexible sealing membrane, in particular for roofs, comprising a thermoplastic material and a reinforcing system, comprising a synthetic fiber grating and a glass fiber grating incorporated in the thermoplastic material, characterized in that the reinforcing grids are chosen such that if the membrane is subjected to a progressive tensile force, the tension exerted at the time of the breaking of the glass fiber grid is at most equal to 90% of the tensile resistance of the synthetic fiber grid. Sealing membrane according to claim 1, characterized in that the glass fiber grid has a tensile resistance of between 5 and 60 daN / 5 cm. Sealing membrane according to claim 1, characterized in that the synthetic fiber grating has a tensile resistance of between 30 and 15 250 daN / 5 cm. Sealing membrane according to any one of claims 1 to 3, characterized in that the weight of the synthetic fiber grid is between 20 and 300 g / m. Sealing membrane according to any one of claims 1-4, characterized in that the weight of the glass fiber grid is between 10 and 200 g / m 2. Sealing membrane according to any one of claims 1 to 5, characterized in that the grid is made of synthetic fibers based on polyester fibers. Sealing membrane according to any one of claims 1 to 6, characterized in that the thermoplastic material is formed from a mixture of chlorinated polyolefin and vinyl chloride-based resins. Sealing membrane according to any one of claims 1-7, characterized in that it has an elongation at break of the most resistant element of between 12 and 20% and has a shrinkage of less than 0.3%. Sealing membrane according to any one of claims 1 to 8, characterized in that it consists successively of a layer of thermoplastic material, a grid of synthetic fibers, a grid of 8501451 IK. ». -i -7- made of glass fibers and a layer of thermoplastic material, which are joined by hot lamination. 8501431